Insights into the Exfoliation Process of V2O5·nH2O ... - ACS Publications

This is an open access article published under a Creative Commons Non-Commercial No Derivative Works (CC-BY-NC-ND) Attribution License, which permits copying and redistribution of the article, and creation of adaptations, all for non-commercial purposes.

Article Cite This: ACS Omega 2019, 4, 10899−10905

http://pubs.acs.org/journal/acsodf

Insights into the Exfoliation Process of V2O5·nH2O Nanosheet Formation Using Real-Time 51V NMR Ahmed S. Etman,†,§,# Andrew J. Pell,† Peter Svedlindh,‡ Niklas Hedin,† Xiaodong Zou,† Junliang Sun,*,†,∥ and Diana Bernin*,†,⊥ †

Department of Materials and Environmental Chemistry, Stockholm University, 10691 Stockholm, Sweden Department of Engineering Sciences, Uppsala University, 75121 Uppsala, Sweden § Department of Chemistry, Faculty of Science, Alexandria University, Ibrahimia, 21321 Alexandria, Egypt ∥ College of Chemistry and Molecular Engineering, Peking University, 100871 Beijing, China ⊥ Department of Chemistry and Chemical Engineering, Chalmers University of Technology, 41296 Gothenburg, Sweden

Downloaded via 37.9.46.16 on August 8, 2019 at 12:21:01 (UTC). See https://pubs.acs.org/sharingguidelines for options on how to legitimately share published articles.

‡

S Supporting Information *

ABSTRACT: Nanostructured hydrated vanadium oxides (V2O5·nH2O) are actively being researched for applications in energy storage, catalysis, and gas sensors. Recently, a onestep exfoliation technique for fabricating V2O5·nH2O nanosheets in aqueous media was reported; however, the underlying mechanism of exfoliation has been challenging to study. Herein, we followed the synthesis of V2O5·nH2O nanosheets from the V2O5 and VO2 precursors in real time using solution- and solid-state 51V NMR. Solution-state 51V NMR showed that the aqueous solution contained mostly the decavanadate anion [H2V10O28]4− and the hydrated dioxovanadate cation [VO2·4H2O]+, and during the exfoliation process, decavanadate was formed, while the amount of [VO2·4H2O]+ remained constant. The conversion of the solid precursor V2O5, which was monitored with solid-state 51V NMR, was initiated when VO2 was in its monoclinic forms. The dried V2O5·nH2O nanosheets were weakly paramagnetic because of a minor content of isolated V4+. Its solid-state 51V signal was less than 20% of V2O5 and arose from diamagnetic V4+ or V5+.This study demonstrates the use of real-time NMR techniques as a powerful analysis tool for the exfoliation of bulk materials into nanosheets. A deeper understanding of this process will pave the way to tailor these important materials.

1. INTRODUCTION In the last few years, the synthesis of two-dimensional (2D) materials based on transition metal chalcogenides and oxides with thicknesses of a few layers has attracted renewed attention because of the different chemical, physical, and semiconducting properties of these materials compared to their bulk (threedimensional, 3D) counterparts.1−3 Vanadium oxides are earthabundant compounds, which have important applications in catalysis,4 batteries,5−7 supercapacitors,8−10 and sensors.11 Thus, many research groups have focused on the synthesis of 2D vanadium oxides from their bulk precursors.12−14 Of particular interest among these 2D materials are those based on the hydrated vanadium pentoxides (V2O5·nH2O), which have been shown to exhibit improved electrochemical behavior and semiconducting properties compared to anhydrous V2O5.15 The improvements are typically ascribed to the presence of H2O or H+ ions between the V2O5 layers in V2O5· nH2O, which can be synthesized in the form of hydrogels,16 xerogels,17,18 nanobelts,19 and nanosheets.5−7 Nanostructured V2O5·nH2O has attracted research interest as it can be easily fabricated into a freestanding film,5 which is easier to handle © 2019 American Chemical Society

than, and is thus advantageous compared to, an amorphous or crystalline powder or gel. V2O5·nH2O is commonly synthesized either by an ionexchange route using sodium metavanadate solution or via a sol−gel route using a mixture of hydrogen peroxide (H2O2) and V2O5.20,21 In both cases, a dark red compound is formed with a layered structure. Recently, Etman et al. synthetized V2O5·nH2O nanosheets using aqueous exfoliation of a mixture of V2O5 and VO2, resulting in black/green films.7 The synthesis was monitored by in situ X-ray diffraction (XRD) studies, which revealed that the V2O5·nH2O phase started to form after 90 min of reflux in water at 80 °C. A more detailed understanding of the underlying mechanism of the formation of this V2O5·nH2O product is challenging because vanadium is a transition metal with a very complex chemistry and many different stable oxidation states.21 As XRD and wide-angle Xray scattering provide data mainly on the long-range order in Received: March 15, 2019 Accepted: May 29, 2019 Published: June 24, 2019 10899

DOI: 10.1021/acsomega.9b00727 ACS Omega 2019, 4, 10899−10905

ACS Omega

Article

compounds, other techniques are important to assess developments in noncrystalline materials or at the solid−liquid interface during the reaction. Nuclear magnetic resonance (NMR) is a characterization technique complementary to XRD and has been used to study the ion-exchange or sol−gel synthesis routes of V2O5· nH2O.22−26 It can provide information about the local order, coordination states, and protonated or deprotonated oxygen atoms. Typically, solid compounds are monitored by magicangle spinning (MAS) solid-state (ss)-NMR, whereas solutionstate NMR is used to observe dissolved compounds. However, both solid- and solution-state 51V NMR are complicated by localized unpaired electrons in paramagnetic V4+ ions, which may bleach out the signal arising from the NMR detectable (diamagnetic) 51V5+ ions in various ways.27 MAS ss-NMR is able to distinguish between delocalized (metallic) and localized (paramagnetic) electronic states via Knight shifts and paramagnetic shifts.28 Paramagnetic, which refers here to Curie or Curie−Weiss paramagnetism, V4+ ions with localized unpaired electrons cannot be directly studied with NMR, but their presence has the effect of bleaching the 51V signal of nearby V5+ ions, allowing the presence of V4+ to be probed indirectly. However, V4+ ions with localized unpaired electrons can be studied by other techniques, for example, electron spin resonance (ESR). When the V4+ ions are less than 2.7 Å apart, their unpaired electrons may pair and turn the corresponding materials from paramagnetic to diamagnetic, which does give a detectable 51V4+ NMR signal.27,29,30 In this paper, we report on real-time solid- and solution-state 51 V NMR studies performed during the synthesis of V2O5· nH2O nanosheets from a 1:4 mixture by weight of commercial monoclinic VO2(M) and V2O5. The interpretation of the 51V NMR results was linked with those from ESR and 1H NMR and used to elucidate the mechanism of the aqueous exfoliation process and formation of V2O5·nH2O nanosheets.

Figure 1. (a) XRD patterns of V2O5·nH2O nanosheets in transmission mode using synchrotron radiation (black) and low-energy X-ray reflection (gray) mode. The remaining traces of the V2O5 phase are marked by “*”. To the right, the TEM image (b) and SAED (c) of the V2O5·nH2O nanosheets are shown. In (c), the inset shows the crystals from which SAED was obtained.

and oxidation states of metal ions. The commercial V2O5 precursor possessed a layered anisotropic structure of distorted VO6 octahedral building units,13,31 and its 51V isotropic shift was −611 ppm (see Figure 2, black).27 The isotropic shift of

2. RESULTS AND DISCUSSION 2.1. Morphology and Structure of V2O5·nH2O Nanosheets. The V2O5·nH2O nanosheets were synthesized in water from a 1:4 mixture by weight of monoclinic VO2(M) and commercial V2O5, and the chemical and thermal analyses are described elsewhere.7 The XRD pattern (Figure 1a, gray) of the as-prepared V2O5·nH2O nanosheets displayed broad peaks, which were indexed as 00l, reflecting the preferred orientation of the layered structure of the nanosheets. This pattern was recorded in a reflection configuration using an in-house diffractometer (λ = 1.5406 Å). One possible solution to overcome the preferred orientation was to perform XRD in transmission mode with, for example, a high-energy X-ray source (synchrotron radiation, λ = 0.7766 Å). Notably, the XRD pattern (see Figure 1a, black) recorded in this way was very similar to that collected in the reflection mode using an inhouse diffractometer, suggesting a disordered stacking between V2O5·nH2O layers over the a−b plane. Interestingly, the transmission electron microscopy (TEM) images showed that V2O5·nH2O had a typical nanosheet morphology with a different lateral size thickness ranging from 30 to 220 nm (see Figure 1b). In addition, the selected area electron diffraction (SAED) pattern of V2O5·nH2O had powder rings (see Figure 1c), which provided additional support for disordered stacking between the layers over the a−b plane. 2.1.1. Local Structure of V2O5·nH2O Nanosheets. MAS ssNMR can provide fruitful information about the local structure

Figure 2. Weight-normalized 51V MAS ss-NMR spectra of V2O5 (black) and V2O5·nH2O nanosheets (red). The signal intensity for V2O5·nH2O is scaled up by a factor of 20. The isotropic shift is marked by “+”.

the largely disordered nanosheets of V2O5·nH2O was slightly lower in magnitude, −596 ppm, and the spinning side band manifold was broader, having nearly double the number of spinning side bands (see Figure 2, red). In addition, the individual side bands exhibited an increased inhomogeneous line width, which suggested highly distorted geometries of the vanadium sites. The enhanced line width was in agreement with observations from XRD and SAED. In previous NMR studies of V2O5·nH2O gels, synthesized using H2O2-based or ion-exchange methods, up to five different 51V NMR peaks have been observed and attributed to various vanadium sites.32,33 The corresponding 51V isotropic shifts have been in the interval of −572 to −663 ppm. However, in this study, the intrinsic and symmetric 51V line width of the 51V NMR peaks of the nanosheets of V2O5·nH2O exceeded 80 ppm and thus prevented potential multiple vanadium sites from being resolved. On the basis of previous studies,32 the 51V isotropic shift of the nanosheets of V2O5· nH2O suggested octahedral vanadium sites with one water 10900

DOI: 10.1021/acsomega.9b00727 ACS Omega 2019, 4, 10899−10905

ACS Omega

Article

rotational restricted motion in hydrated V2O5 as evidenced by the features of the 2H powder patterns.22 In this work, neither bulk H2O nor strongly coordinated H2O could be observed. Instead, the features of the static 2H spectrum suggested that H2O had a high mobility. However, H2O or −OH groups bonded or coordinated to V4+ were not easily detectable under static conditions, as they were expected to be strongly shifted by a Fermi-contact shift to the paramagnetic V4+ ion, exhibit large resonance broadening, and have short relaxation times. The observed 2H chemical shifts at 3.3 and 1 ppm were attributed to D2O and −OD on the surface of the nanosheets, respectively.38 The chemical shift at 7 ppm may have been due to −OD groups, in which the O atom bridges between two V atoms. 2.2. Probing Nanosheet Formation by Real-Time 51V NMR. To elucidate the formation of nanosheets, we applied real-time solid- and solution-state 51V NMR to follow the reaction of the solid phases and the dissolved species separately. 2.2.1. Dissolved Species. VO2 and V2O5 with a mass ratio of 1:4 were blended with 550 μL of H2O and 50 μL of D2O in an NMR tube, and solution-state 51V NMR spectra were recorded in real time during the reaction. The observed vanadium species and their 51V shift are summarized in Table 1. It was

molecule bonded to the vanadyl oxygen or vanadium pentoxide with shifted subunits. Notably, the integral intensity of the total 51V signal including the spinning side band manifold of the V2O5·nH2O nanosheets was less than 20% of the V2O5 precursor. The broad line width of the side bands means that the second-order quadrupolar broadening cannot be measured from the line shape, and the contributions of the first-order quadrupolar interaction and shift anisotropy to the spinning side band manifold cannot be easily separated; consequently, the quadrupolar couplings were not measured.34 One possible reason for the signal loss relative to the precursor would be a phase transition similar to that of VO2(M)−metallic-VO2(R) because of frictional heating from MAS.35,36 The magnetic susceptibility data (see Figure S1) indicated a weak paramagnetic behavior of the nanosheets with no observable magnetic phase transition. A fit of these data returned a Weiss constant of zero, pure Curie paramagnetism which we ascribe to isolated (noninteracting) V4+ ions that were incorporated between the V2O5 nanosheets during the course of the reaction. In turn, we ascribe the large reduction in the observable signal from V2O5 to a paramagnetic bleaching effect, where the nuclear relaxation of V5+ is enhanced by the proximity of the paramagnetic V4+ ions.27 As the synthesis was performed in an aqueous mixture of VO2(M) and V2O5, the former provided a possible source of paramagnetic V4+, given the 1:4-fraction of VO2(M) and V2O5. V2O5·nH2O has been found to contain about 10 mol % of V4+ according to Etman et al.,7 which was in agreement with the observed weakly paramagnetic behavior. The presence of V4+ was here confirmed by ESR (see Figure S2). The corresponding spectra each had a broad peak with an isotropic g-value of 1.95 at room temperature. This value matched well with those reported for other V4+-containing materials.23,29,37 2.1.2. Water Molecules in V2O5·nH2O Nanosheets. The distribution and location of H2O in V2O5·nH2O are important for the electrochemical behavior and semiconducting properties.20,21 In relation to the positioning of H2O, Pozarnsky and McCormick suggested a chain model with a H2O molecule and a −OH group in the equatorial plane and an additional H2O pointing downward.25 Hence, we recorded a static 2H ss-NMR spectrum (see Figure 3) on the V2O5·nD2O nanosheets and observed three distinct resonances with decreasing intensities at chemical shifts of 1, 3.3, and 7 ppm. Similar results were obtained from 1H NMR experiments under MAS, but the 1H background of the probe and rotor complicated the interpretation (data not shown). Takeda et al. have observed

Table 1. Dissolved Vanadium Species Observed with Solution-State NMRa dissolved vanadium species [H2V10O28]4− [VO2·4H2O]+ a

51

V shift (ppm)

−419, −503, −522 −549

The peak at −297 ppm could not be assigned.

evident that the 51V signals of the decavanadate anion [H2V10O28]4−, resonating at −419, −503, and −522 ppm, exhibited increasing integral intensities for up to 2 h after mixing, whereas the 51V signal of the hydrated dioxovanadate cation [VO2·4H2O]+ at −549 ppm retained a constant integral (see Figure 4). The decavanadate anion is believed to be produced from 10 dioxovanadate cations under acidic conditions in aqueous solutions. However, if this reaction had occurred here, there must also have been an additional process where dioxovanadate cations were produced. Fur-

Figure 4. Stacked real-time solution-state NMR spectra as a function of time. “x” marks an unassigned peak. The inset shows the normalized 51 V signal integral as a function of time for [H2V10O28]4− (black) and [VO2·4H2O]+ (red).

Figure 3. Static 2H NMR of V2O5·nD2O nanosheets. The 2H NMR spectrum was recorded using a quadrupolar echo sequence. 10901

DOI: 10.1021/acsomega.9b00727 ACS Omega 2019, 4, 10899−10905

ACS Omega

Article

Figure 5. Low-flip-angle direct excitation (a) and Hahn echo (b) MAS ss-NMR spectra at 70 °C for the VO2/V2O5 mass ratio of 1:4 extracted from real-time experiments at time = 0 (black trace) and time = 38 h (red trace). (c) Normalized 51V integrals vs time for reactions with aged VO2 (blue) or fresh VO2 (Hahn echo red; direct excitation gray) in the reaction mixture. The black curve is a repetition using a Hahn echo.

Etman et al. have reported on an onset of the V2O5·nH2O formation after 90 min using real-time XRD,7 while the formation of decavanadate leveled out after 2.5 h. By comparing those findings with the ones of this study, the question arose if the dissolved species were responsible for the formation of nanosheets or if the observations of the decavanadate anion and the dioxovanadate cation were solely due to various side reactions of the aqueous vanadium chemistry. Many mechanisms have been proposed for the formation of nanostructured gels,23−25,37 and in our view, the most relevant are those that have dealt with ion exchange.23,25 However, notably, all of them have derived these compounds from vanadium-based species in solution, whereas here we instead started from two commercial solid compounds (V2O5 and VO2). 2.2.2. Solid Species. To access information on the solid phases during the reaction, we performed real-time MAS ssNMR experiments on the reaction mixture (0.3 mg of VO2, 1.2 mg of V2O5, and 20 μL of H2O) at 7 kHz MAS. Analyses of the 51 V NMR spectra in Figure 5a,b showed a reduction of the integral of the whole 51V signal spinning side band manifold due to the V2O5 phase, which has an isotropic chemical shift of −611 ppm. The reduction was observed both for low-flip-angle direct excitation (Figure 5c, gray) and in a Hahn echo experiment (Figure 5c, red). The normalized 51V NMR integrals of a repeated Hahn echo experiment (Figure 5c, black) coincided well with the first reaction. Vanadiumcontaining compounds have a very large 51V NMR shift range, which in turn required that we moved the observation window by changing the carrier frequency and retuning the probe to observe various species. By comparing weight-normalized 51V MAS ss-NMR spectra of fresh commercial VO2(M) and V2O5, the observed broad 51V signal of VO2(M) at approximately 2100 ppm30 was consistent with